Note : Les descriptions sont présentées dans la langue officielle dans laquelle elles ont été soumises.
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TRACTION CLEAT AND RECEPTACLE
[01]
FIELD OF THE INVENTION
[02] The present invention pertains to footwear cleats for primary use in
field sports and,
more particularly, to improvements in such cleats that result in improved
traction and
safety without adversely impacting running speed. It is to be understood that
the cleats
described herein, although having particular advantages when used to enhance
traction
in field sports, are not limited to such use, and can be used with golf shoes
and in other
applications where cleats depend from the outsole of a shoe to enhance
traction during
walking, running, pivoting, etc. In addition, as described herein, the cleats
may be
removably attached to a shoe outsole or molded permanently into the outsole.
BACKGROUND
[03] Cleats secured to footwear used in soccer, rugby, lacrosse, cricket,
American
football and other field sports have typically taken the form of individual
replaceable
hard plastic or metal studs that threadedly engage respective receptacles
mounted in
the outsole of an athletic shoe. Depending on player preferences and
conditions, the
studs typically range in length from ten millimeters to eighteen millimeters.
For muddy
and similar poor field conditions, longer studs are conventionally more
desirable
because they penetrate the ground more deeply to provide better traction. That
is, it is
the surface area of the stud in contact with the sod (i.e., the turf and top
soil) below the
ground level that engages the sod for traction during a push-off for a running
step or
during an attempt to stop. Therefore, more stud surface area makes contact
with the
sod as penetration into the sod increases. However, when studs penetrate the
sod
more deeply, the wearer is unable to run as fast as he/she would be able to
when there
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is less penetration. For example, a 15mm stud penetrates the ground only to
approximately 10mm on initial impact and, as the runner pushes off to take the
next
step, the downward force causes the stud to initially sink further toward the
maximum
15mm depth. This is referred to as secondary sink or penetration, the
limitation of
which is defined by the outsole of the shoe abutting the ground. The result of
secondary penetration is a significant loss of power on the push off for each
step,
thereby limiting running speed. In addition, a not insignificant amount of the
wearer's
energy (i.e., force and time) is used in withdrawing a long stud from the
muddy turf with
each step.
[04] Apart from the loss of push-off power, long studs are believed to cause
many
field sport injuries. The longer the stud, the more deeply anchored it becomes
in the
turf. When studs are deeply anchored, forces suddenly applied to ankles, legs
and
knees are more likely to create injuries since the stud and shoe cannot
readily break
away from the turf in response to sudden momentum changes of the runner and
lateral
impact from collisions and tackling. In other words, when the shoe does not
easily
break away from the turf, a portion of the leg is more likely to break or
become sprained
in response to lateral forces applied to a knee or leg.
[05] It is known to provide golf shoes with plastic cleats that provide
traction without
penetrating the ground. This is a highly desirable characteristic for golf
shoe cleats
because ground penetration, particularly on putting greens, can damage the
grass root
system and leave uneven terrain that adversely affects the ability to
accurately putt a
golf ball. A highly efficient type of golf cleat for this purpose provides
dynamic traction
wherein traction elements on the cleat flex, typically spreading outwardly,
under the load
of the wearer's weight and, in doing so, provide the desired traction without
ground
penetration. Examples of dynamic traction cleats may be found, for example, in
U. S.
Patent Nos. 6,209,230, 6,305,104 and 7,040,043. In these patents, cleats are
disclosed
which take the form of a hub with a connector such as a threaded shaft
extending from
the hub top surface that can be selectively secured to a mating
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connector mounted in a golf shoe outsole. Plural flexible traction elements
extend
generally downward and outward from the hub periphery to frictionally engage
the
surface, become entangled with grass blades and turf, and trap grass blades
against
the shoe outsole, all of which combine to provide traction as the traction
elements flex
under the weight of the wearer. It is the flexure of the traction elements
that give these
cleats the name "dynamic traction cleats" and distinguish them from plastic
cleats
wherein the plural traction elements are inflexible, or "static", and provide
only the more
limited traction resulting from direct point to point contact on the ground
surface.
[06] One approach to overcoming the aforementioned disadvantages of the
conventional soccer stud is disclosed in U.S. Patent Application Publication
No.
2009/0211118 (Krikorian et al, U. S. Patent Application Serial No. 12/393,451)
wherein
dynamic traction is used to reduce secondary penetration by field studs into
muddy and
soggy sod. Specifically, the cleat comprises a hub, a stud of substantially
non-flexible
material extending downwardly from a lower surface of the hub, a cleat
connector
extending upwardly from an upper surface of the hub, and dynamic traction
elements
extending downwardly from the lower surface of the hub, typically from the hub
rim, and
adapted to flex upwardly when the cleat is connected to a shoe. The distal end
of the
stud is substantially flat or slightly rounded (e.g., beveled) and extends
further from the
lower surface of the hub than the distal end of each unflexed dynamic traction
element
such that, when the shoe to which the cleat is connected is forced downward
toward the
ground surface, the stud contacts and/or begins to penetrate the ground
surface to
provide initial traction before each dynamic traction element makes contact
with the
ground surface. The dynamic traction elements thus reduce the secondary
penetration
of the stud and eliminate some of the disadvantages described above.
[07] We have found that even the initial penetration of the stud disclosed in
Krikorian
et al adversely affects the speed and quickness of the wearer of the shoe
because of
the effort required to remove the stud from that penetration. Moreover, even
the initial
penetration has been found to be undesirable from a safety/injury perspective
for the
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reasons described. It would be desirable, therefore, to utilize dynamic
traction in a field
cleat without a penetrating stud.
[08] Initially, in studying the above-stated problems, we conducted
experiments
involving attaching to field sport athletic shoes some commercially available
versions of
the dynamic traction cleats disclosed in U.S. Patent Nos. 6,305,104 (available
commercially as BLACK WIDOW cleats under the Softspikes brand) and 7,040,043
(available commercially as PULSAR cleats under the Softspikes brand). It was
found
in field sports tests that traction was not as reliable as desired because the
dynamic
traction elements did not efficiently entangle with and trap grass blades in
response to
sudden starts, stops and directional changes by the player wearing the shoe.
Moreover, it was also discovered that the dynamic traction elements were
becoming
damaged in response to the shear and torsional stresses produced by those
sudden
momentum changes.
[09] Further, in some instances the attachment between the cleat and the
receptacle
was compromised in response to sudden momentum changes. Specifically, the
BLACK
WIDOW and PULSAR cleats employ the very reliable FAST TWIST locking system of
the type disclosed in U.S. Patent Nos. 6,810,608 and 7,107,708. In that system
a
circular array of locking posts are angularly spaced and uniformly arranged
about the
cleat hub. The receptacle is provided with a continuous ring of multiple
adjacent locking
teeth of generally triangular configuration such that the apices of successive
teeth click
past the interfering locking posts and then more firmly engage the locking
posts as the
threaded engagement between the cleat and receptacle is tightened (i.e., as
the
threaded cleat stem is rotated further into the threaded receptacle socket).
Although
this arrangement functions perfectly when used in golf shoes, we found that
the
engagement between the posts and teeth is often compromised when subjected to
the
stresses of sudden starts, stops and turns experienced by shoes used in field
sports.
[010] It is desirable, therefore, and an object of the invention, to provide a
cleat and
cleat receptacle that utilize dynamic traction effectively, reliably and
safely when used in
field sports shoes.
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SUMMARY OF THE INVENTION
[011] In accordance with one aspect of the invention the radial thickness of
the
dynamic traction element (i.e., in the dimension radially outward from the
traction
element central longitudinal axis) is substantially increased to enlarge the
cross-
sectional area of the traction element and the mass of polymer contained
therein as
compared to the dynamic traction elements on commercially available golf
cleats. The
cross-sectional area of the traction element may be taken in any plane that is
generally
perpendicular to a line extending longitudinally through the traction element
sections.
Although increasing the angular width of the traction elements would also
increase the
cross-sectional area of the traction element and possibly increase its
strength, doing so
would reduce the space available for traction elements. We have found that if
the radial
thickness is increased sufficiently to prevent traction element damage from
expected
shear and torsional stresses, but not so much as to prevent sufficient flexure
of the
element to enable it to spread outwardly to engage turf surfaces and grass
blades and
to also trap grass blades against a shoe outsole, the resulting dynamic
traction is more
efficient and effective than what is provided by conventional penetrating
studs. In
particular, we found that providing a cross-sectional area of at least twenty
square
millimeters throughout the traction element length provides a significant
increase in
traction element strength. In a preferred and optimum embodiment the traction
element
was provided with a transverse section that varies throughout its length and
was at least
thirty square millimeters at its thickest part. This compares, for example, to
the BLACK
WIDOW golf cleat wherein the transverse cross-sectional area at the thickest
section
of the traction element is on the order of fourteen square millimeters.
[012] By increasing the radial thickness of the traction element, the
resulting increase
of thermoplastic material forming the traction element, and thereby the
increase in
traction element mass, is also substantial. In particular, the volume of
polymer forming
each traction element in the aforesaid preferred and optimum embodiment is
approximately one-hundred-ninety-seven cubic millimeters; this is in
comparison to a
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volume of approximately sixty-two cubic millimeters for the traction element
in the
BLACK WIDOW golf cleat.
[013] The radial thickening of the traction element also includes an increase
in the
surface area of its turf-engaging distal end. In the aforementioned preferred
and
optimum embodiment, that surface area is approximately 15.6 mm2; the
corresponding
surface are for the BLACK WIDOW golf cleat is approximately 4.1 mm2. This
almost
fourfold increase in surface area for each traction element has proven
effective in
increasing traction resulting from surface friction as the traction elements
flex outwardly
under weight load and push the contact surfaces of the traction elements along
the turf.
[014] The thusly improved dynamic traction elements are able to resist
damaging
torsional and shear stresses when entangled with grass blades and when forced
against the turf, yet they provide the desired reliable and effective dynamic
traction
without safety risks to the athlete resulting from ground penetration.
Importantly,
traction for this cleat is provided by the dynamic elements tangling with
grass and
trapping grass against the outsole, and by ground surface friction, not by
penetration
into the ground. The result of this construction is that the cleat releases
from its
engagement with the turf at very close to the same shear forces for every
step,
irrespective of the weight of the athlete wearing the shoe. This may be
compared to
cleats having a central stud in combination with surrounding dynamic elements
wherein
the stud digs into the ground to a depth determined by the wearer's weight,
thereby
rendering the traction weight dependent.
[015] In some instances it may be desirable to provide support for the dynamic
traction
elements in addition to that provided by the enhanced thickness. In such cases
a
central wear pad may be provided to extend from the bottom surface of the hub
with an
axial length shorter than that of the dynamic elements so as to minimize
damage to the
dynamic elements from full flexure extension on hard surfaces such as cement
walkways. The axial length of the wear pad is selected such that, in response
to
downward force by the foot of the wearer of the shoe, the dynamic elements
initially
contact the ground and deflect sufficiently to engage and trap grass blades
against the
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shoe sole just as the wear pad contacts the ground. In other words, the wear
pad is
prevented by the dynamic elements from penetrating turf and does not interfere
with the
tractional effects provided by the dynamic elements or contribute
significantly to the
tractional forces provided by dynamic elements. Wear pads, per se, are well
known and
may take the shape of a short vertical projection with a flat or rounded
distal end, a
spherical segment, a plurality of spaced projections from the bottom of the
hub with
rounded or flat distal ends, etc.
[016] On the other hand, we have found that the overall tractional effect
improves as
the wear pad is made shorter to permit the dynamic legs to fully flex.
Therefore, there is
tradeoff between tractional force improvement and the protection of the
dynamic
elements on hard surfaces. Specifically, the traction provided by the cleat on
grass
(artificial or natural) results from the dynamic elements spreading outwardly
to both
become entangled with grass blades and to trap grass blades against the
outsole, as
well as surface friction at the point of turf contact; the greater the
spreading, the greater
the traction. Thus, if wear pad projection is provided, its length must be
selected
sufficiently shorter than the downward projection of the unflexed dynamic
elements to
permit the elements to maximally flex and optimize tractional effects. In
addition, the
wear pad projection must be sufficiently short and properly configured to
prevent it from
penetrating the ground under user weight loading.
[017] Another feature of the present invention is the recognition that in
field sports such
as soccer, rugby, etc., the traction requirements differ significantly at
different locations
of the outsole. As a consequence, some or all of the cleats, depending on
their
attachment locations on the shoe outsole, may have a combination of dynamic
and
static elements, or only dynamic elements, or only static elements. In
addition, separate
static elements may project from the shoe outsole at locations adjacent
dynamic
elements on a cleat to protect the dynamic elements on hard surfaces in a
manner
similar to a wear pad.
[018] It is also within the scope of the invention to have the radially
thickened traction
elements extend from the cleat hub outwardly and down (i.e., diverging
downwardly
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from the cleat axis), straight down or, in some cases, inwardly down (i.e.,
converging
downwardly toward the cleat axis) to achieve the desired traction effects.
[019] A further feature of the invention is the enhanced strength of the
attachment
system and locking arrangement by which the cleat is retained in the
receptacle
mounted in the shoe outsole. In this regard the continuous ring of multiple
triangular
locking teeth of the aforementioned FAST TWIST system that is used in
connection
with golf shoes is replaced by an annular series of angularly spaced locking
stubs
having increased angular length. The number of stubs is equal to the number of
locking
posts, and the stubs are configured such that, in the locked position of the
cleat in the
receptacle, each stub is positioned between and abuts or is engaged by two
locking
posts. The side edges of the posts and stubs are configured to permit the
posts to
readily pass along the stubs during insertion of the cleat in a first
rotational direction but
to strongly resist passage of the posts when rotation is attempted in the
opposite
direction. The greater mass and edge configuration of the stubs, as compared
to
triangular configuration and lesser mass of the prior continuous array of
multiple locking
teeth, provides for enhanced strength in the locking function.
[020] In the preferred embodiment of the invention attachment of the cleat and
receptacle is effected by a two-start threaded engagement between an
externally
threaded stem projecting from the cleat hub and a corresponding threaded
socket in the
receptacle.
[021] The above and still further features and advantages of the present
invention will
become apparent upon consideration of the following definitions, descriptions
and
figures of specific embodiments thereof wherein like reference numerals in the
various
drawings are utilized to designate like components. While these descriptions
go into
specific details of the invention, it should be understood that variations may
and do exist
and would be apparent to those skilled in the art based on the descriptions
herein.
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BRIEF DESCRIPTION OF THE DRAWINGS
[022] FIG. 1 is view from below in perspective of a first embodiment of a
traction cleat
according to the present invention.
[023] FIG. 2 is a view from above in perspective of the traction cleat of FIG.
1.
[024] FIG. 3 is a top view in plan of the traction cleat of FIG. 1.
[025] FIG. 4 is a bottom view in plan of the traction cleat of FIG. 1.
[026] FIG. 5 is a first view in elevation and partial section of the cleat of
FIG. 1, taken
along lines 5 ¨ 5 of FIG. 4.
[027] FIG. 6 is a second view in elevation and partial section of the cleat of
FIG. 1,
taken along lines 6 ¨ 6 of FIG. 4.
[028] FIG. 7A is a view in section similar to FIG. 6 but showing traction
elements in
separate shading.
[029] FIG. 7B is a view in section taken transversely of a traction element
leg along
lines B ¨ B of FIG. 7A.
[030] FIG. 7C is a view in section taken transversely of a traction element
leg along
lines C - C of FIG. 7A.
[031] FIG. 8 is a view from below in perspective of a receptacle for receiving
the cleat
of FIG. 1 according to the present invention.
[032] FIG. 9 is a bottom view in plan of the receptacle of FIG. 8.
[033] FIG. 10 is a top view in plan of the receptacle of FIG. 8.
[034] FIG. 11 is an elevation view in section of the receptacle of FIG. 8.
[035] FIG. 12 is an exploded view in perspective of a second embodiment of a
traction
cleat according to the present invention.
DETAILED DESCRIPTION
[036] Referring specifically to FIGS. 1 ¨7, a cleat 10 has a threaded
attachment stem
20 projecting from the top surface of a hub 11 about a cleat longitudinal axis
A for
attachment to a receptacle described below in connection with FIGS. 8 ¨ 11. In
the
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preferred embodiment of the cleat the thread on the stem is a two-start
thread. The hub
11 in the preferred embodiment is generally circular and concentric about axis
A and is
defined within an annular perimeteric edge 12. A plurality of angularly spaced
dynamic
traction elements 13 have proximal ends secured at or near edge 12 and extend
outward and downward therefrom. Specifically, each traction element 13
includes a
proximal section 14 extending outward and slightly downward from a respective
location
substantially at edge 12, and a distal section 15 extending substantially
downward from
the distal end of the proximal section 14. The distal section terminates in a
turf-
engaging end surface 16 which is slightly convex and devoid of sharp corners
or edges.
The dynamic traction elements 13 are sufficiently flexible relative to the hub
as to be
pivotally flexible in an upward direction about perimeteric edge 12 when
subjected to the
weight of a typical person wearing a shoe in which the cleat is installed.
[037] A set of six locking posts 17 are disposed in angularly spaced
relationship in an
annular array located concentrically about the cleat axis A. Each locking post
has a
radially inward facing surface 21 disposed between first and second end
surfaces 18,
19, respectively. A radially outer surface joins the outer edges of the end
surfaces.
Posts 17 project perpendicularly upward (i.e., axially) from the top surface
of hub 11.
Each end surface 18, 19 is provided in two discrete segments, a first or
rearward
segment that extends perpendicularly inward from the outer surface, and a
second or
forward segment that bends at an angle forwardly from the rearward segment and
intersects inward facing surface 21. The angle of the bend between segments in
end
surface 18 (e.g., on the order of 45 ) is considerably sharper than the angle
of the bend
between segments in end surface 19 (on the order of 65 ) so as to provide a
shallower
angular slope at what serves as the leading edge of the post. As described in
more
detail below, the shallow slope facilitates rotational passage of the posts
past locking
stubs on the receptacle as the cleat is rotationally installed in the
receptacle. The
steeper slope at the radially forward segment of end surface 19 serves as the
trailing
edge and provides a greater impediment to rotation of the cleat in the
direction opposite
the insertion direction.
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[038] The top surface of the locking posts preferably slopes slightly (i.e.,
on the order of
16 in the preferred embodiment) from the leading end to the trailing end. The
axial
height of the posts in the preferred embodiment is nominally approximately
3.05 mm,
and the radial thickness of the posts is approximately between one and two
millimeters.
As shown in the drawings the six spaces between the six posts 17 may comprise
annular recesses or cutouts in the perimeteric edge 12 of the hub so as to
reduce the
amount of polymer material required for the hub.
[039] The radial thickness of the traction elements 13 throughout their
lengths is
substantial; it is sufficient, in fact, to prevent traction element damage
from expected
shear and torsional stresses when used in connection with field sports.
However, the
radial thickness is not so great as to prevent sufficient flexure of the
element to enable it
to spread outwardly to engage turf surfaces and grass blades and to also trap
grass
blades against a shoe outsole. In particular, although the traction element
has a varying
peripheral contour along its length, it is radially thicker at every point
along its length
than the traction elements provided on cleats used with golf shoes. Consider,
for
example, the cross-section of the traction element illustrated in FIG. 7B,
taken along
lines B ¨ B in FIG. 7A, wherein the cross-sectional area is approximately
twenty-five
square millimeters (actually, 25.45 mm2 in a preferred embodiment). The
corresponding
cross- section of the aforementioned commercially available BLACK WIDOW golf
cleat
has an area of only 11.77 mm2. Consider next the section of the traction
element
illustrated in FIG. 7C, taken along lines C ¨ C in FIG. 7A, wherein the cross-
sectional
area is approximately thirty-two square millimeters (actually, in the
preferred
embodiment, 32.07 mm2). The corresponding section of the aforementioned BLACK
WIDOW golf cleat has an area of only 13.78 mm2. For purposes of the present
invention, the required functions as described herein are achieved where the
traction
element has a transverse cross-sectional area that varies throughout its
length and is at
least twenty square millimeters and preferably has a maximum cross-sectional
area of
at least thirty square millimeters.
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[040] Another feature of the cleat that enhances traction for field sports,
particularly
traction resulting from surface friction, is the relatively large turf-
engaging end surface
16. Specifically, in the preferred embodiment the area of surface 16 is
approximately
fifteen square millimeters (actually, in the preferred embodiment, 15.65 mm2).
The
corresponding surface of the aforementioned BLACK WIDOW golf cleat has an
area of
only 4.14 mm2.
[041] As noted above, increasing the thickness of the traction element in the
radial
dimension of the cleat results in an increase of the amount of thermoplastic
material
forming the traction element and, thereby, an increase in traction element
mass. In the
preferred embodiment the volume of material in the traction element is
approximately
one-hundred-ninety-seven cubic millimeters; this is in comparison to a volume
of
approximately sixty-two cubic millimeters for the traction element in the
BLACK WIDOW
golf cleat.
[042] Referring to FIGS. 8 ¨ 11 in greater detail, there is illustrated a
receptacle 30 that
is configured to receive, engage and securely lock in place the cleat of FIG.
1 described
above. With the exception of the locking stubs and the two-start thread
described
below, receptacle 30 is conventional in its configuration and includes a base
31 having a
bottom surface 33 and a top surface 32. The base is generally rectangular with
rounded corners but can be otherwise configured, symmetrically or
asymmetrically
about receptacle attachment axis B. When cleat 10 is installed in receptacle
30, cleat
axis A and receptacle axis B are coaxially positioned. An outer portion of
base 31 has a
plurality of mounting slots defined longitudinally therethrough for securing
the
receptacle in a shoe sole. More particularly, mounting of the receptacle in
the shoe
outsole is effected by methods well known in the art and may include forming
the
outsole material around the mounting slots, or compression molding such as the
process disclosed in U. S. Patent No. 6,248,278 (Kelly), etc. A generally
cylindrical
hollow boss 34 projects from bottom surface 33, centrally on the base, and
defines a
hollow generally cylindrical interior or cavity 35 disposed concentrically
about the
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receptacle longitudinal axis B. The distal end wall 36 of the boss is open to
provide
access to the cavity. The interior wall of the cavity is threaded with a two-
start thread
configured to receive and threadedly engage the cleat stem 20.
[043] Boss 34 projects perpendicularly from the top surface of the base plate.
The
outer cylinder is open at one end and closed at its base. Concentrically
disposed about
the boss is an outer cylinder. An annular receiving space is defined between
the boss
and outer cylinder, the distal annular lower edges of which are coplanar. The
threaded
boss socket extends deeper into the body of the base than does the annular
receiving
space between the boss and outer cylinder, thereby providing more depth for
the
threaded socket which increases the strength of its threaded engagement to
resist the
high sheer forces experienced in field sports.
[044] Six equally angularly spaced locking stubs 40 are disposed in an annular
array
on the radially outer surface of the cylindrical boss 34. The angular spacing
between
the stubs in the preferred embodiment is approximately 22 and each stub
subtends an
angle of approximately 38 ; the radial thickness of the stubs is approximately
1.0 mm.
Each stub includes a radially outer face 41 and two end walls, 42, 43
subtending
different respective angles with the outer surface of boss 34 from which the
stubs
project. Specifically, the angle between end wall 42 and the boss outer
surface is
greater than the angle between end wall 43 and that surface, so that the slope
presented by that end wall to ends and edges of locking posts 17 on cleat 10
is
shallower than the steeper slope presented by end wall 43.
[045] An important aspect of the locking arrangement provided for cleat 10 and
receptacle 30 is that the stubs 40 are angularly spaced from one another wit
annular
gaps along the outer surface of boss 34. This is as opposed to having an end
of one
stub in contact or in immediate adjacency with the next stub in the array as
is the case
when a ring of sequentially connecting locking teeth are provided in the
aforementioned
FAST TWIST arrangement. In addition, the mass of the stubs 40, by virtue of
their
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larger size as compared to the prior locking teeth, renders the stubs more
resistant to
disengagement of the cleat and receptacle.
[046] The outward facing surface 41 or each stub 40 is slightly convex with a
radius of
curvature about receptacle axis B. The inward facing surface 21 of each cleat
locking
post 17 is slightly concave with a radius of curvature about cleat axis A.
Outward facing
surface 41 of the stub is at a radial distance from post axis B that is
slightly greater
(e.g., by approximately one millimeter) than the radial distance of surface 21
of each
post from cleat axis A. This results in an interfering engagement between
these
surfaces when they are angularly (i.e., rotationally) aligned.
The posts 17 are
somewhat rigid but sufficiently flexible to be able to bend slightly radially
about their
bases as the posts rotationally pass the stubs during insertion of the cleat
in the
receptacle. The shallow sloping leading ends 18 of the post and shallow
sloping
leading end walls 42 of the stubs facilitate rotation as these surfaces engage
and
gradually force the post flexure during insertion rotation. Once the posts
pass the stubs
and reside in angular alignment with the spaces between the stubs, the posts
return to
their nominal shapes. When stem 20 is fully threadedly inserted in cavity 35,
the stem
distal end abuts the closed end of the cavity and the entire axial lengths of
the posts are
fully inserted. It is in this final insertion position that the steeper angled
trailing ends of
the posts and stubs fully abut along their axial lengths and preclude mutual
rotation
between the cleat and receptacle in a direction opposite to the insertion
direction.
[047] More specifically, in attaching the cleat 10 to receptacle 30,
externally threaded
cleat stem 20 is rotated in internally threaded receptacle cavity 35 until the
entire stem
is received in the cavity. As the stem is rotated about axes A and B in the
cavity, posts
17 are angularly forced past successive stubs 40. Initially, the shallow
sloped leading
ends 18 of posts 17 are readily rotated past the shallow leading end walls 42
of stubs
40 with more and more of the axial lengths of the posts and stubs engaging as
rotation
continues. When the stub 20 is fully axially inserted, each post resides at
least partially
radially inserted into a respective space between two stubs, and each trailing
end wall
43 abuts the trailing end surface 19 of a respective post and resists rotation
opposite
14
CA 02891675 2016-10-20
the insertion direction. With each passage of the posts past the stubs during
insertion,
the installer receives both tactile and audible "click" indications (i.e.,
provided by the
posts being forced resiliently past a stub and into the next recess). In
addition, since
more of the axial length of the posts is engaged and resiliently deformed
during each
stub pass, the rotational force required is greater for successive steps. As a
consequence, the installer is made readily aware when a cleat is partially or
fully
inserted.
[048] The cleat illustrated in FIG. 12 is in two parts, the cleat structure
itself and a
threaded attachment stud which extends through a central aperture in the cleat
hub,
such as that illustrated in FIG. 8, to threadedly engage a receptacle mounted
in the
outsole of a shoe. This type of attachment is well known in the art and is
exemplified by
the attachment system illustrated and described in U. S. Patent Application
Publication
No. 2009/0211118. It is to be understood that the attachment stud may also be
an
integral part of the cleat and configured to extend upwardly from the top
surface of the
hub.
[049] It should be noted that the traction elements 13 of cleat 10 need not be
segmented into angularly oriented arm and leg portions but instead can be
formed as a
single straight section appropriately angled downwardly and outward from the
hub. The
important feature is the large radial thickness and resulting mass that
protects the
traction element against damage while still permitting flexure to achieve
dynamic
traction. Specifically, we have found that increasing the dynamic traction
element radial
thickness throughout most of its length, relative to the element thickness in
the BLACK
WIDOW and PULSAR cleats, by at least twenty percent and even more than sixty
percent, produces these desired results. In addition, each dynamic leg may
include a
generally triangular reinforcing gusset extending inward from its interior
facing surface
to the bottom surface of the hub in a conventional manner to enhance the
strength of
the leg.
[050] The specific dimensions described herein are for a preferred embodiment
of the
cleat and provide the necessary thickness to optimize traction while
minimizing damage
CA 02891675 2015-05-15
WO 2014/100119 PCT/US2013/076010
to those traction elements. Those dimensions are provided only as examples of
preferred embodiments and are not, of themselves, to be taken as limiting the
scope of
the invention which is to be determined by the attached claims.
[051] The commercial version of the FAST TWIST locking system referred to
hereinabove as used with golf cleats typically employs a three-start thread.
The reason
for using a two start thread in the present invention is related to the fact
that the
threaded center post in the present invention is longer than in the standard
FAST
TWIST system. This adds strength to the engagement to combat the higher
stresses
experienced in fields sports. However, it is desirable to minimize the
rotation of the
cleat in the receptacle to 90 or 120 achieve full insertion of the cleat. In
order to
accommodate these competing requirements without increasing the height of the
overall
attachment system (i.e., receptacle and cleat attachment section), the number
of
threads was reduced to two and the threads were made stronger. Specifically,
as
compared to the standard FAST TWIST system, the height of each thread has
been
increased by twenty-eight percent while maintaining the same system height and
providing for a quarter turn (90 ) installation. In addition, the thread core
in the present
system is larger by seven percent to provide greater strength and stiffness.
This has
been accomplished by increasing the outside diameter of the socket by only
three
percent, thereby keeping the overall design extremely compact.
[052] Although the combination of relatively large dynamic traction element
mass and
the locking system provided between the cleat and receptacle described herein
functions particularly well for field sport shoes using replaceable cleats, it
should be
noted that the cleat of the present invention may also be permanently molded
or
otherwise formed as part of the outsole of a shoe. In such an embodiment the
molding
of the cleat into the shoe outsole provides the connection strength and the
large mass
of the dynamic traction elements provides the required traction with
sufficient strength to
substantially reduce the risk of damage to the traction elements by shear and
similar
forces during field sports use. When the cleat is molded into the shoe
outsole, the
dynamic elements may extend downwardly from the bottom surface of the outsole,
or
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WO 2014/100119 PCT/US2013/076010
the cleat may include a hub of different material from the outsole and which
is co-
molded to reside substantially flush with the outsole bottom surface with the
dynamic
traction elements extending from that hub as described herein fro the
replaceable cleat.
[053] The relative terms "top", "bottom", "upper', "lower" "above", "below",
"forward",
"rear", "height", "length", "width", "thickness", and the like as used herein
are for ease of
reference in the description to merely describe points of reference and are
not intended
to limit any particular orientation or configuration of the described subject
matter.
[054] Having described preferred embodiments of new and improved traction
cleat and
receptacle and various novel components thereof, it is believed that other
modifications,
variations and changes will be suggested to those skilled in the art in view
of the
teachings set forth herein. It is therefore to be understood that all such
variations,
modifications and changes are believed to fall within the scope of the present
invention
as defined by the appended claims. Although specific terms are employed
herein, they
are used in a generic and descriptive sense only and not for purposes of
limitation.
17
